首页 | 本学科首页   官方微博 | 高级检索  
     

自驱动Janus微球近壁运动特性实验与数值模拟研究
引用本文:崔海航,谭晓君,张鸿雁,陈力. 自驱动Janus微球近壁运动特性实验与数值模拟研究[J]. 物理学报, 2015, 64(13): 134705-134705. DOI: 10.7498/aps.64.134705
作者姓名:崔海航  谭晓君  张鸿雁  陈力
作者单位:西安建筑科技大学环境与市政工程学院, 西安 710055
基金项目:西安建筑科技大学创新团队,国家自然科学基金应急管理项目理论物理专款(批准号:11447133)资助的课题.
摘    要:自驱动Janus微球是形状规则但表面构成不同的特殊活性颗粒. 针对微米级Pt-SiO2型Janus 微球近壁面自驱动现象, 实验测得了微球的自驱动速度VJanus, 并观察到微球运动过程中与垂直方向存在一偏转仰角ψ, 且ψ角随H2O2溶液浓度的增大呈减小趋势. 在此基础上, 建立自驱动Janus微球的数值模型, 通过模拟得到了微球在不同浓度H2O2溶液中的偏转仰角ψ及距底面的高度δ, 模拟与实验一致. 利用这些数据进一步讨论了壁面效应对微球旋转特征时间τR的影响. 这一工作对于理解Janus 微球的运动机理及发展相关应用具有重要意义.

关 键 词:Janus微球  自驱动  近壁效应  旋转扩散
收稿时间:2014-12-25

Experiment and numerical study on the characteristics of self-propellant Janus microspheres near the wall
Cui Hai-Hang,Tan Xiao-Jun,Zhang Hong-Yan,Chen Li. Experiment and numerical study on the characteristics of self-propellant Janus microspheres near the wall[J]. Acta Physica Sinica, 2015, 64(13): 134705-134705. DOI: 10.7498/aps.64.134705
Authors:Cui Hai-Hang  Tan Xiao-Jun  Zhang Hong-Yan  Chen Li
Affiliation:School of Environment and Municipal Engineering, Xi'an University of Architecture and Technology, Xi'an 710055, China
Abstract:Self-propellant Janus microsphere is a special class of active particles with a regular shape and irregular surface characteristic. With the self-propulsion of 2 μm diameter Pt-SiO2 Janus microsphere near the wall, we have measured the relationship of self-propellant velocity VJanus versus the observed time Δtobs. A diffusiophoretic force-dominated motion, which can be deemed as a quasi-1 D motion with the characteristics of both force free and torque free, is distinguished from the entire motion process. At the same time, it is also observed that the Janus microsphere is deflected about the vertical direction with an angle ψ. The deflection angle ψ is found to decrease with the increase of H2O2 concentration in the solution. For the 2.5%-10% H2O2 solution in this experiment, the angle ψ ranges from 20° to 7° approximately. A numerical model, involving viscous force, diffusiophoretic force and the effective gravity, is created with a reference frame, this quasi-1 D self-propellant motion can be solved to satisfy the conditions of the force and torque balance simultaneously. We have studied the changes of angle ψ and separation distance δ of the microsphere from the substrate under different conditions, including the concentrations of H2O2 solution, the material density, and the diameter of the microsphere. For the self-propulsion velocity VJanus and the deflection angle ψ, numerical results show good agreement with the published experimental observation results. Moreover, it is found that the lower density or the smaller diameter of the microsphere will generate the smaller distance δ, while the higher concentration of H2O2 in the solution will result in a larger distance δ. The predicted δ is 2-8 μm. With the obtained data, we further discuss the effect of near wall on the characteristic time τR of rotational diffusion of the Janus microsphere. Because the predicted values of δ are relative high, the near wall effect can be neglected, indicating that this effect should not be a significant factor to cause a big discrepancy of τR in different references. The present work will be beneficial to the understanding of the mechanism of self-propulsion and the development in its potential applications.
Keywords:Janus microsphere  self-propulsion  near wall effect  rotational diffusion
点击此处可从《物理学报》浏览原始摘要信息
点击此处可从《物理学报》下载免费的PDF全文
设为首页 | 免责声明 | 关于勤云 | 加入收藏

Copyright©北京勤云科技发展有限公司  京ICP备09084417号